Abstract: An enhancement-mode device comprises: a substrate, an epitaxial multilayer structure formed on the substrate, and a gate region formed on the epitaxial multilayer structure, where the epitaxial multilayer structure sequentially comprises from the substrate: a nucleation layer, a buffer layer, a heterojunction structure layer, a second gallium nitride layer, a nitride transition layer and a dielectric layer, where the heterojunction structure layer comprises a gallium nitride channel layer and a barrier layer which has a sandwich structure, and a middle layer of the sandwich structure is a first gallium nitride layer; and the gate region comprises a gate metal layer and a p-type nitride layer located under the gate metal layer, wherein the p-type nitride layer is embedded into the epitaxial multilayer structure, a bottom of the p-type nitride layer is in contact with the first gallium nitride layer of the sandwich structure.

Abstract: A light emitting device includes a double-sided electrode type semiconductor light emitting element that has a first electrode formed on a front side of the double-sided type semiconductor light emitting element and a second electrode formed on a rear side of the double sided type semiconductor light emitting element and is configured to emit light from a side wall surface of the double-sided electrode type semiconductor light emitting element, a first lead frame that is bonded to a whole area of one face of the first electrode, a second lead frame that is bonded to a whole area of one face of the second electrode, and a case in which a portion of the first lead frame and a portion of the second lead frame is embedded,

Abstract: A semiconductor device that includes one semiconductor device formed in one semiconductor material and a second semiconductor device formed in another semiconductor material on a common substrate, and a method of fabricating the semiconductor device.

Abstract: Embodiments of the present invention provide an improved finFET and methods of fabrication. A sigma cavity is used with an n-type finFET to allow multiple epitaxial layers to be disposed adjacent to a finFET gate. In some embodiments, stacking faults may be formed in the epitaxial layers using a stress memorization technique.

Abstract: In at least one embodiment, a surface light source includes one or a more optoelectronic semiconductor chips having a radiation main side for generating a primary radiation. A scattering body is disposed downstream of the radiation main side along a main emission direction of the semiconductor chips. The scatting body is designed for scattering the primary radiation. A main emission direction of the scattering body is oriented obliquely with respect to the main emission direction of the semiconductor chip.

Abstract: This disclosure discloses an LED assembly. The LED assembly comprises a transparent substrate; a first phosphor layer; a transparent mount, having a plurality of trenches substantially in parallel to each other, wherein the first phosphor layer is positioned between the transparent substrate and the transparent mount; an LED chip, mounted on an area of the transparent mount, wherein the area is located substantially between the trenches; and a second phosphor layer inside the trenches.

Abstract: Solid state light emitting apparatuses include blue LEDs (including but not limited to a combination of short wavelength and long wavelength blue LEDs) to stimulate green lumiphors, with supplemental emissions by either red lumiphors and/or red solid state light emitters, to provide aggregate emissions with high S/P ratio (e.g., at least 1.95) and favorably high color rendering values (e.g., 85 or greater), preferably in combination with high brightness and high luminous efficacy. In certain embodiments, a solid state light emitting apparatus may be devoid of a LED having a peak wavelength of from 470-599 nm and/or devoid of lumiphors peak wavelengths in the yellow range. Multiple LEDs may be arranged in an emitter package.

Abstract: [Problem] To provide a chip-on-board light emitting device and a method for manufacturing the same such that even though the light emitting device is a chip-on-board light emitting device, it is possible to improve color rendering thereof without excessively reducing the amount of light emission and without installing special circuit patterns or performing current control. [Solution] A chip-on-board light emitting device in which a plurality of LED elements are mounted directly on a package substrate includes a circuit pattern formed on the package substrate, the circuit pattern including a plurality of mounting sections on which the plurality of LED elements are mounted and an anode electrode and cathode electrode pair.

Abstract: A light-emitting diode (LED) is provided. An LED die includes a first semiconductor layer, a light-emitting layer, a second semiconductor layer, a first electrode and a second electrode. At least a part of the first semiconductor is exposed from the light emitting layer and the second semiconductor layer. The first electrode and the second electrode is disposed on top of the exposed first semiconductor layer and the second semiconductor layer respectively. At least two metal pads are disposed on top of the first electrode and the second electrode of the LED die respectively. Each of the metal pads has a side surface. A fluorescent layer is disposed on a surface of the LED die. The fluorescent layer directly contacts with the side surfaces of the metal pads and fills a gap between the metal pads.

Abstract: Various methods and apparatuses are disclosed. A method may include disposing at least one die on a location on a carrier substrate, forming at least one stud bump on each of at least one die, forming a phosphor layer on the at least one stud bump and the at least one die, removing a top portion of the phosphor layer to expose the at least one stud bump, and removing a side portion of the phosphor layer located between two adjacent dies. An apparatus may include a die comprising top, bottom, and side surfaces. A phosphor layer may be disposed on the top, bottom, and side surfaces of the die. The phosphor layer may have substantially equal thicknesses on the top and side surfaces of the die as well as one or more stud bumps disposed on the top surface of the die.

Abstract: A method of producing the crystalline substrate having a concave-convex structure includes: (A) forming a transfer film by forming a concave-convex film on a support film on the surface having a concave-convex pattern thereon so that thickness of the residual film of the concave-convex film is 0.01 to 1 ?m, the concave-convex pattern of the support film having concave parts with a width of 0.05 to 100 ?m, a depth of 0.05 to 10 ?m, and a ratio of the depth of the concave part to the width of the concave part of up to 1.5, (B) disposing the transfer film on the crystalline substrate, and transferring the concave-convex film onto the crystalline substrate to produce a crystalline substrate having the concave-convex film thereon, (C) etching the crystalline substrate having the concave-convex film thereon to form a concave-convex structure on the surface of a crystalline substrate.

Abstract: A light emitting diode including a magnetic structure and a method of fabricating the same are disclosed. The magnetic structure composed of passivation layers and a magnetic layer is disposed inside a luminous structure composed of an active layer and a semiconductor layer. In the light emitting diode, the magnetic structure including the magnetic layer is disposed on a side surface of the active layer to improve recombination rate of charge carriers for light emission by increasing influence of a magnetic field applied to the active layer. In addition, the light emitting diode according to the present invention allows change in position of the magnetic structure including the magnetic layer depending upon an etched shape of the luminous structure, thereby realizing various magnetic field distributions.

Abstract: A method of manufacturing package component for light emitting diode (LED) is disclosed. At least one LED is disposed on a substrate inside a photocuring resin, wherein the LED is covered completely by the substrate and the photocuring resin. Power is provided to the LED to make the LED emit plural light beams such that a portion of the photocuring resin is cured by the light beams to obtain a male mold. A separation process is performed to separate the male mold and the other portion of the photocuring resin, the LED and the substrate. A rollover process is performed to manufacture the female mold by the male mold, wherein the female mold has at least one accommodation space with a shape identical to that of the male mold. A forming process is performed to form a package component with a shape identical to that of the male mold.

Abstract: A semiconductor chip structure including a semiconductor chip having a pair of electrodes is disclosed. The electrodes have different conductivity types for electrical connection, respectively. A thermoelectric cooling material layer is disposed within each of the pair of electrodes, respectively.

Abstract: According to one embodiment, a composite resin includes a resin component; and a plurality of first powder bodies dispersed in the resin component. Each of the first powder bodies has a nonlinear current-voltage characteristic having a decreasing resistance as a voltage increases. The first powder body is a polycrystalline powder body including a plurality of primary particles bound via a grain boundary. A component different from a major component of the primary particles exists in a higher concentration in the grain boundary than in an interior of the primary particles.

Abstract: A semiconductor device including a Si (110) substrate, a buffer layer, a first type doped semiconductor layer, a light-emitting layer and a second type doped semiconductor layer is provided. The Si (110) substrate has a plurality of trenches. Each trench at least extends along a first direction, and the first direction is parallel to a <1-10> crystal direction of the Si (110) substrate. The buffer layer is located on the Si (110) substrate and exposes the trenches. The first type doped semiconductor layer is located on the buffer layer and covers the trenches. The light-emitting layer is located on the first type doped semiconductor layer. The second type doped semiconductor layer is located on the light-emitting layer. A fabrication method of a semiconductor device is also provided.

Abstract: A method for fabricating a composite device comprises providing a platform, providing a chip, and bonding the chip to the platform. The platform has a base layer and a device layer above the base layer. An opening in the device layer exposes a portion of the base layer. The chip is bonded to the portion of the base layer exposed by the opening in the device layer. A portion of the chip extends above the platform and is removed.

Abstract: A composite photonic device comprises a platform, a chip, and a contact layer. The platform comprises silicon. The chip is made of a III-V material. The contact layer has indentations to help control a flow of solder during bonding of the platform with the chip. In some embodiments, pedestals are placed under an optical path to prevent solder from flowing between the chip and the platform at the optical path.

Abstract: A method for forming a semiconductor device includes forming a mask layer on a stressed semiconductor layer of a stressed, semiconductor-on-insulator wafer. An isolation trench bounding the stressed semiconductor layer is formed. The isolation trench extends through the mask layer and into the SOI wafer past an oxide layer thereof. A dielectric body is formed in the isolation trench. A relaxation reduction liner is formed on the dielectric body and on an adjacent sidewall of the stressed semiconductor layer. The mask layer on the stressed semiconductor layer is removed.

Abstract: Embodiments of an apparatus comprising a pixel array including a plurality of pixels formed in a substrate having a front surface and a back surface, each pixel including a photosensitive region formed at or near the front surface and extending into the substrate a selected depth from the front surface. A filter array is coupled to the pixel array, the filter array including a plurality of individual filters each optically coupled to a corresponding photosensitive region, and a vertical overflow drain (VOD) is positioned in the substrate between the back surface and the photosensitive region of at least one pixel in the array.

Abstract: Structures, apparatuses, and methods are provided for fabricating a semiconductor device structure. An example semiconductor device structure includes a first substrate, a first device layer, a second device layer and a third device layer. The first device layer may be on the first substrate and include a switch. The second device layer may be on the first device layer and include a sensing device. The third device layer may include one or more inter-level connection structures configured to electrically connect the switch to the sensing device. The switch may be configured to be electrically turned on in response to a selection signal. The sensing device may be configured to generate an output signal in response to the switch being turned on.

Abstract: Embodiments of mechanisms for forming a micro-electro mechanical system (MEMS) device are provided. The MEMS device includes a CMOS substrate and a MEMS substrate bonded with the CMOS substrate. The CMOS substrate includes a semiconductor substrate, a first dielectric layer formed over the semiconductor substrate, and a plurality of conductive pads formed in the first dielectric layer. The MEMS substrate includes a semiconductor layer having a movable element and a second dielectric layer formed between the semiconductor layer and the CMOS substrate. The MEMS substrate also includes a closed chamber surrounding the movable element. The MEMS substrate further includes a blocking layer formed between the closed chamber and the first dielectric layer of the CMOS substrate. The blocking layer is configured to block gas, coming from the first dielectric layer, from entering the closed chamber.

Abstract: A semiconductor device includes a channel having a first linear surface and a first non-linear surface. The first non-linear surface defines a first external angle of about 80 degrees to about 100 degrees and a second external angle of about 80 degrees to about 100 degrees. The semiconductor device includes a dielectric region covering the channel between a source region and a drain region. The semiconductor device includes a gate electrode covering the dielectric region between the source region and the drain region.

Abstract: A semiconductor device includes a semiconductor substrate and attenuated semiconductor fins (e.g. FinFET fins) that include an outer portion that is a composite of a first material and a second material, an inner portion that is the second material, and an attenuation portion that is an attenuated composite of the first and second materials. The attenuation portion may be formed by diffusing the first material into a plurality of fins made of the second material. The attenuated composite attenuates from a first composite to a second composite, the first composite comprising a majority of the first material, the second composite comprising a majority of the second material. The outer portion may be located on the fin perimeter and the inner portion may be located central to the fin. The first material may be Germanium, the second material may be Silicon, and the attenuated composite may be attenuated Silicon Germanium.

Abstract: A semiconductor device includes a first channel having a first linear surface and a first non-linear surface. The semiconductor device includes a first dielectric region surrounding the first channel. The semiconductor device includes a second channel having a third linear surface and a third non-linear surface. The semiconductor device includes a second dielectric region surrounding the second channel. The semiconductor device includes a gate electrode surrounding the first dielectric region and the second dielectric region.

Abstract: An image capturing device includes an intermediate region located between a pixel circuit region and a peripheral circuit region and forming a boundary with the pixel circuit region and the peripheral circuit region. The pixel circuit region, the peripheral circuit region, and the intermediate region are provided with a semiconductor layer, a first wiring layer on the semiconductor layer, and a second wiring layer located away from the semiconductor layer relative to the first wiring layer. Pixel circuits and a peripheral circuit are connected via one of at least the first wiring layer and the second wiring layer in the intermediate region. The area occupancy of the one wiring layer in the intermediate region relative to a total area thereof is between 0.5 times and 1.5 times the area occupancy of the one wiring layer in the pixel circuit region relative to a total area thereof.

Abstract: A fin-shaped field-effect transistor device is provided. The fin-shaped field effect transistor device may include a semiconductor substrate having a top and a bottom surface. The fin-shaped field effect transistor device may also include a fin structure disposed on the top surface of the semiconductor substrate, where the fin structure includes a first sidewall and a second sidewall opposite of the first sidewall. The first sidewall is adjacent to a first region of the top surface of the semiconductor substrate and the second sidewall is adjacent to a second region of the top surface of the semiconductor substrate. The fin-shaped field effect transistor device may also include an insulation layer disposed above the fin structure and the first and second regions of the top surface. The fin-shaped field effect transistor device may also include a conductor structure disposed above and adjacent to the insulation layer.

Abstract: A semiconductor FET provides a resonant gate and source and drain electrodes, wherein the resonant gate is electromagnetically resonant at one or more predetermined frequencies.

Abstract: A semiconductor device is provided. A channel layer is formed on a substrate. The channel layer is extended in a first direction substantially perpendicular to an upper surface of the substrate. A ground selection line is formed on a first region of the channel layer. A plurality of word lines is formed on a second region of the channel layer. A plurality of string selection lines is formed on a third region of the channel layer. The second region of the channel layer includes a first conductivity type dopant. The first, second and third regions of the channel layer are disposed along the first direction.

Abstract: A device comprises a control gate structure over a substrate, a memory gate structure over the substrate, wherein the memory gate structure comprises a memory gate electrode and a memory gate spacer, and wherein the memory gate spacer is over the memory gate electrode, a charge storage layer formed between the control gate structure and the memory gate structure, wherein the charge storage layer is an L-shaped structure, a first spacer along a sidewall of the memory gate structure, a first drain/source region formed in the substrate and adjacent to the memory gate structure and a second drain/source region formed in the substrate and adjacent to the control gate structure.

Abstract: A system and method for providing electrical isolation between closely spaced devices in a high density integrated circuit (IC) are disclosed herein. An integrated circuit (IC) comprising a substrate, a first device, a second device, and a trench in the substrate and a method of fabricating the same are also discussed. The trench is positioned between first and second devices and comprises a first filled portion and a second filled portion. The first filled portion of the trench comprises a dielectric material that forms a buried trench isolation for providing electrical isolation between the first and second devices.

Abstract: A semiconductor device has a vertical drain extended MOS transistor with deep trench structures to define a vertical drift region and at least one vertical drain contact region, separated from the vertical drift region by at least one instance of the deep trench structures. Dopants are implanted into the vertical drain contact regions and the semiconductor device is annealed so that the implanted dopants diffuse proximate to a bottom of the deep trench structures. The vertical drain contact regions make electrical contact to the proximate vertical drift region at the bottom of the intervening deep trench structure. At least one gate, body region and source region are formed above the drift region at, or proximate to, a top surface of a substrate of the semiconductor device. The deep trench structures are spaced so as to form RESURF regions for the drift region.

Abstract: A vertically oriented field effect device has a body and an enhance gate structure. The body includes a JFET (junction field effect transistor) region disposed between junction implants that extend into the body from a top surface of the body. The gate structure includes a supplemental gate dielectric, a primary gate dielectric, and a gate contact. The supplemental gate dielectric is formed over the top surface of the body above the JFET region, such that the supplemental dielectric is separated from the junction implants by a gap. The primary gate dielectric is formed over the supplemental gate dielectric, above the gap over the top surface of the body, and over at least a portion of the junction implants. The gate contact is formed over the primary gate dielectric.

Abstract: A semiconductor device includes a first type region including a first conductivity type. The semiconductor device includes a second type region including a second conductivity type. The semiconductor device includes a channel region extending between the first type region and the second type region. The semiconductor device includes a gate region surrounding the channel region. The gate region includes a gate electrode. A gate electrode length of the gate electrode is less than about 10 nm. A method of forming a semiconductor device is provided.

Abstract: Provided is a method for fabricating a semiconductor device, which includes the following steps. First, a substrate having at least one transistor is provided. A first insulation layer is formed to cover the transistor. The first insulation layer is patterned to form at least one opening, wherein a part of the transistor is exposed by the opening. At last, an epitaxy is formed in the opening to cover the part of the transistor.

Abstract: A three-dimensional (3-D) nonvolatile memory device includes channel layers protruding perpendicular to a surface of a substrate, interlayer insulating layers and conductive layer patterns alternately formed to surround each of the channel layers, a slit formed between the channel layers, the slit penetrating the interlayer insulating layers and the conductive layer patterns, and an etch-stop layer formed on the surface of the substrate at the bottom of the slit.

Abstract: A semiconductor device having a vertical drain extended MOS transistor may be formed by forming deep trench structures to define vertical drift regions of the transistor, so that each vertical drift region is bounded on at least two opposite sides by the deep trench structures. The deep trench structures are spaced so as to form RESURF regions for the drift region. Trench gates are formed in trenches in the substrate over the vertical drift regions. The body regions are located in the substrate over the vertical drift regions.

Abstract: A semiconductor device having a vertical drain extended MOS transistor may be formed by forming deep trench structures to define at least one vertical drift region bounded on at least two opposite sides by the deep trench structures. The deep trench structures include dielectric liners. The deep trench structures are spaced so as to form RESURF regions for the drift region. Vertical gates are formed in vertically oriented gate trenches in the dielectric liners of the deep trench structures, abutting the vertical drift regions. A body implant mask for implanting dopants for the transistor body is also used as an etch mask for forming the vertically oriented gate trenches in the dielectric liners.

Abstract: A semiconductor device has a plurality of gate electrodes over a gate insulator layer formed in active trenches located in an active region of a semiconductor substrate. A first gate runner is formed in the semiconductor substrate and electrically connected to the gate electrodes. The first gate runner abuts and surrounds the active region. A second gate runner is connected to the first gate runner to make contact to a gate metal. A dielectric filled trench surrounds the first and second gate runners and the active region and a highly doped channel stop region is formed under the dielectric filled trench.

Abstract: A semiconductor device includes a vertical IGFET in a first area of a semiconductor body, the vertical IGFET having a drift zone between a body zone and a drain electrode, the drift zone having a vertical dopant profile of a first conductivity type being a superposition of a first dopant profile declining with increasing distance from the drain electrode and dominating the vertical dopant profile in a first zone next to the drain electrode and a second dopant profile being a broadened peak dopant profile and dominating the vertical dopant profile in a second zone next to the body zone.

Abstract: A half-bridge circuit includes a low-side transistor and a high-side transistor each having a load path and a control terminal, and a high-side drive circuit having a level shifter with a level shifter transistor. The low-side transistor and the level shifter transistor are integrated in a common semiconductor body.

Abstract: A semiconductor device is disclosed. The device includes a plurality of gates formed on a surface of a substrate, a plurality of sidewalls formed on side surfaces of the gates, a Sigma-shaped recess formed in the substrate between adjacent gates, a SiGe seed layer formed on an inner surface of the Sigma-shaped recess, boron-doped bulk SiGe formed on a surface of the SiGe seed layer, with the boron-doped bulk SiGe filling the Sigma-shaped recess, and a boron-doped SiGe regeneration layer formed in a first recess beneath the surface of the substrate. The first recess is formed by etching a portion of the SiGe seed layer and the boron-doped bulk SiGe in the Sigma-shaped recess, and the boron-doped SiGe regeneration layer has a higher concentration of boron than the SiGe seed layer or the boron-doped bulk SiGe.

Abstract: A lateral drain metal oxide semiconductor (LDMOS) device includes a well region having a second conductive type in a substrate, a body region having a first conductive type in the well region, a drift region having the second conductive type in the well region and spaced apart from the body region, a source region having the second conductive type in the body region, a drain region having the second conductive type in the drift region, a gate structure on the well region between the source region and the drain region, a shallow trench isolation (STI) structure in the drift region between the drain region and the source region, and a buried layer having the first conductive type in the well region under the drift region, a center of the buried layer being aligned with a center of the STI structure.

Abstract: A problem associated with n-channel power MOSFETs and the like that the following is caused even by relatively slight fluctuation in various process parameters is solved: source-drain breakdown voltage is reduced by breakdown at an end of a p-type body region in proximity to a portion in the vicinity of an annular intermediate region between an active cell region and a chip peripheral portion, arising from electric field concentration in that area. To solve this problem, the following measure is taken in a power semiconductor device having a superjunction structure in the respective drift regions of a first conductivity type of an active cell region, a chip peripheral region, and an intermediate region located therebetween: the width of at least one of column regions of a second conductivity type comprising the superjunction structure in the intermediate region is made larger than the width of the other regions.

Abstract: A device includes a semiconductor substrate, source and drain regions disposed in the semiconductor substrate, having a first conductivity type, and laterally spaced from one another, and a composite body region disposed in the semiconductor substrate and having a second conductivity type. The composite body region includes a first well region that extends laterally across the source and drain regions and a second well region disposed in the first well region. The drain region is disposed in the second well region such that charge carriers flow from the first well region into the second well region to reach the drain region. The second well region includes dopant of the first conductivity type to have a lower net dopant concentration level than the first well region. A pocket may be disposed in a drain extension region and configured to establish a depletion region along an edge of a gate structure.

Abstract: A FinFET comprises a substrate comprising a major surface; a fin structure protruding from the major surface comprising a lower fin portion comprising a first semiconductor material having a first lattice constant; an upper fin portion comprising a second semiconductor material having a second lattice constant greater than the first lattice constant; a middle fin portion comprising a third semiconductor material having a third lattice constant between the first lattice constant and the second lattice constant; and a passivation structure surrounding the fin structure comprising a lower passivation portion surrounding the lower fin portion comprising a first oxynitride of the first semiconductor material; an upper passivation portion surrounding the upper fin portion comprising a second oxynitride of the second semiconductor material; and a middle passivation portion surrounding the middle fin portion comprising a third oxynitride of the third semiconductor material.

Abstract: Devices and methods for forming a device are presented. The method includes providing a substrate having at least a first region and a second region prepared with isolation regions. The first region is referred to as a chip guarding area and the second region defines a chip region of which at least one transistor is to be formed. The substrate includes a top surface layer, a support substrate and an insulator layer in between them. A transistor is formed in the second region and a substrate contact structure is formed in the first region. The substrate contact structure passes through at least the top surface layer, insulator layer and isolation region and contacts a doped region in the support substrate. The substrate contact structure is connected to at least one conductive line with a desired potential to prevent charging of the support substrate at system level.

Abstract: The transverse mechanical stress within the active region of a MOS transistor is relaxed by forming an insulating incursion, such as an insulated trench, within the active region of the MOS transistor. The insulated incursion is provided at least in a channel region of the MOS transistor so as to separate the channel region into two parts. The insulated incursion is configured to extend in a direction of a length of the MOS transistor. The insulated incursion may further extend into one or more of a source region or drain region located adjacent the channel region of the MOS transistor.

Abstract: A Fin-FET fabrication approach and structure are provided using channel epitaxial regrowth flow (CRF). The method includes forming a Fin-FET structure including a Si line on a substrate, shallow trench isolation (STI) oxide on both sides of the Si line on the substrate, and a poly wall on top of and across the STI oxide and the Si line, wherein the Si line is higher than the STI oxide from the substrate. The method further includes thinning the STI oxide and the Si line while maintaining about the same height ratio of the Si line and the STI oxide, and forming a spacer wall adjacent to both sides of the poly wall and further adjacent to Si and STI oxide side walls under the poly wall uncovered due thinning the STI oxide and the Si line.

Abstract: A semiconductor device comprises first and second gate stacks formed on a semiconductor-on-insulator (SOI) substrate. The SOI substrate includes a dielectric layer interposed between a bulk substrate layer and an active semiconductor layer. A first extension implant portion is disposed adjacent to the first gate stack and a second extension implant portion is disposed adjacent to the second gate stack. A halo implant extends continuously about the trench. A butting implant extends between the trench and the dielectric layer. An epitaxial layer is formed at the exposed region such that the butting implant is interposed between the epitaxial layer and the dielectric layer.